A glass manufacturing apparatus includes a glass ribbon gripping device including a first column of jaw clamps spaced from one another along a first clamp path extending in a glass ribbon travel direction of the glass manufacturing apparatus. The glass manufacturing apparatus includes a second column of jaw clamps spaced from one another along a second clamp path extending in the glass ribbon travel direction of the glass manufacturing apparatus. The first column of jaw clamps and the second column of jaw clamps are spaced apart in a lateral direction perpendicular to the glass ribbon travel direction. Additionally, methods of manufacturing a glass ribbon with the glass manufacturing apparatus are provided.

A method and a support for holding a substrate, wherein the support is included in a transportation system configured to transport the substrate. The method includes attaching an adhesive to the support, wherein the material of the adhesive is a synthetic setae material and wherein the adhesive is configured to attach the substrate to the support; and attaching the adhesive to the substrate. Moreover, the thickness of the substrate is about 0.3 mm or less, and/or wherein the substrate has a size of 1.4 m.sup.2 or more. The support includes a support body and an adhesive, wherein the material of the adhesive is a synthetic setae material and wherein the adhesive is configured to attach the support body to the substrate, wherein the support is included in a transportation system configured to transport the substrate.

A window manufacturing system includes a first wire, a second wire spaced apart from the first wire, a controller moving the first wire up and down and the second wire up and down, and a load carrier connected to the first wire and the second wire. Window substrates are disposed on the load carrier. The controller moves the first wire and the second wire in opposite directions to each other.

Apparatus and method for transferring a substrate are disclosed. The substrate transfer apparatus includes: a substrate conveyance assembly disposed between a mechanical arm and a wafer stage, the substrate conveyance assembly including a substrate loading conveyor and a substrate unloading conveyor parallelly arranged in a first direction, each of the substrate loading conveyor and the substrate unloading conveyor configured for transferring a substrate between the wafer stage and the mechanical arm along a second direction perpendicular to the first direction; an integral frame; and a transition air suspension assembly fixed to the integral frame at the end thereof proximal to the wafer stage, the transition air suspension assembly being able to engage with either of the substrate loading conveyor and the substrate unloading conveyor for producing an air film to levitate the substrate during the conveyance of the substrate by the substrate loading conveyor or the substrate unloading conveyor.

A process and apparatus for handling a rigid sheet is disclosed. The process comprises engaging opposing faces of a sheet at its periphery with engagement means providing a second engagement means, movable relative to the first and engaging the sheet with the second engagement means. The sheet is then moved relative to the second engagement means whilst the sheet is engaged with the first engagement means and is then clamped. The sheet is then moved to a desired orientation or location whilst maintaining the first and second engagement means in fixed relative position. The process is useful in handling glass sheeting and in the production of multiple glazed units and on an insulating glass production line.

A glass-plate working apparatus 1 includes: two grinding worktables 17A and 17B which undergo NC controlled movement or angularly controlled rotation independently of each other and a grinding head 18 which undergoes NC controlled movement in correspondence with the grinding worktables 17A and 17B, wherein the grinding worktables 17A and 17B are adapted to alternately move in a planar coordinate system in cooperation with the grinding head 18 and alternately repeat operation in which while one of the grinding worktables 17A and 17B, while holding a glass plate 2, is effecting the grinding of the glass plate 2 by the grinding head 18, the other one of the grinding worktables 17A and 17B effects an operation of discharging the glass plate 2 and receiving a next glass plate 2, to thereby allow the grinding head 18 to proceed with grinding on a continual basis.

A glass-plate working apparatus 1 includes a cutting section 2 serving as a processing position for forming cut lines on a glass plate 5, a grinding section 3 serving as a processing position for grinding peripheral edges of the glass plate 5, a bend-breaking section 4 serving as a processing position between the cutting section 2 and the grinding section 3, and a glass-plate transporting section 6 for transporting the glass plates 5, and further includes a feed conveyor 7 disposed on the side of carrying in to the cutting section 2 and serving as a glass-plate carrying-in section, as well as a discharge conveyor 8 disposed on the side of carrying out from the grinding section 3 and serving as a glass-plate carrying-out section.

The present invention provides a non-contact vibration suppression device comprising a first ultrasonic vibration unit and a second ultrasonic vibration unit, the device being characterized in that the first ultrasonic vibration unit and the second ultrasonic vibration unit are installed to face each other while being spaced from each other such that an object can be interposed therebetween, the first ultrasonic vibration unit and the second ultrasonic vibration unit generate ultrasonic vibrations, respectively, and apply repulsive forces, which result from the ultrasonic vibrations, to the object such that the object is constrained with no contact between the first ultrasonic vibration unit and the second ultrasonic vibration unit, thereby suppressing vibration of the object. In addition, the present invention provides an object processing method characterized by comprising the steps of: suppressing vibration of the object using the non-contact vibration suppression device; and processing the object, vibration of which has been suppressed.

An apparatus and method for guiding a glass substrate positioned in a vertical orientation into a downstream process. A pair of guide arms move with the glass substrate and constrain lateral movement of an otherwise unsupported bottom edge of the glass substrate. Sensors sense a position of the glass substrate, while a controller calculates a speed of the glass substrate in a conveyance direction and positions the guide arms.

The present disclosure relates to a method for manufacturing a bent component. The present disclosure moreover relates to a shaping tool for manufacturing a bent component. The shaping tool comprises a first tool half, a second tool half and at least one movable cylinder pin. The first tool half of the shaping tool is arranged opposite the second half of the shaping tool. An outer end of the at least one cylinder pin herein points in the direction of the second half of the shaping tool. A holding element for receiving a flat bendable element is assembled on this outer end of the at least one cylinder pin.